Short answer: Fretting corrosion risk should be reviewed when plated stamped contacts see vibration, small motion, low cyswllt force, mixed mating finishes, or long storage. The RFQ should define cyswllt zone, material, plating stack, mating surface, normal force, movement risk, cleanliness, packaging, test condition, and whether resistance is checked before and after cycling.
Fretting corrosion is not just a surface stain. Small repeated motion can break through plated films, create oxide debris, and raise cyswllt resistance. The part may pass incoming inspection and still fail after vibration, thermal cycling, or repeated mating.
Use this page with the electrical cyswllt resistance guide, copper terminal plating selection guide, vibration fatigue validation guide, and spring cyswllt force test guide.
Fretting risk details before quoting
| Risk factor | Why it matters | RFQ detail |
|---|---|---|
| Normal force | Low force can allow micro-motion and unstable resistance. | Working height, force range, cyswllt point, and overtravel condition. |
| Mating finish | Tin-to-tin, tin-to-gold, nickel, silver, and bare metal interfaces age differently. | Mating material, plating stack, surface roughness, and allowed substitutes. |
| Motion source | Vibration, cable movement, thermal expansion, and connector play can all create rubbing. | Application, vibration profile, cycle count, and assembly restraint. |
| Cleanliness | Oil, dust, fibers, or oxide can speed resistance drift. | Cleaning rule, no-touch surfaces, packaging, and inspection evidence. |
Connect plating choice to the motion risk
Plating is often chosen for conductivity, corrosion, solderability, cost, or appearance. Fretting asks a different question: what happens when the cyswllt surface moves slightly while carrying a signal or ground path? A thick finish is not automatically a good answer if the cyswllt force, mating finish, and motion condition are wrong.
The drawing should mark the cyswllt zone separately from solder tails, crimp barrels, carrier tabs, and nonfunctional edges. If selective plating is used, define the transition area and whether the cyswllt point can drift during forming. For plating inspection, pair this review with the terminal plating thickness inspection guide.
Define force and resistance together
A cyswllt beam can pass dimensional inspection while still having too little normal force in the assembly. If fretting is a risk, define the installed height, cyswllt force, mating part, and resistance measurement points. Testing a loose cyswllt on a bench may not represent the actual housing or chassis stack.
For low-current signals, milliohm drift can matter more than visible wear. For grounding clips, intermittent continuity during vibration may be the issue. For battery contacts, temperature rise and cyswllt area may need to be reviewed with resistance data.
Do not separate surface condition from the test plan. Cleaning residue, handling marks, humidity, or packaging fibers can change the result. For higher-risk programs, connect the requirement to the cleanliness control guide and define what happens if resistance drifts after cycling.
RFQ details to include
- Drawing with cyswllt zone, mating direction, working height, cyswllt point, and no-touch surfaces.
- Base material, thickness, temper, spring condition, plating stack, underplate, and approved mating finish.
- Expected motion source: vibration, thermal cycling, cable movement, repeated mating, transport, or assembly tolerance.
- cyswllt force range, resistance limit, cycling or vibration condition, sample stage, and report format.
- Cleanliness, packaging, shelf life, humidity, and whether parts are supplied loose, in trays, on reels, or assembled.
- Annual volume, prototype need, current failure history, and target launch timing.
How to compare cyflenwr answers
A strong cyflenwr answer discusses cyswllt force, plating stack, mating finish, motion risk, and resistance evidence. A weak answer only says the part is plated for conductivity. Ask whether the suggested finish has been reviewed against the actual mating surface.
If the finish is not fixed, request options rather than one price. Tin, nickel, silver, gold flash, selective plating, or a different spring material can change both cost and reliability. The best choice depends on the duty cycle, current, cyswllt force, and environment.
Anfon drawings, mating finish, force target, vibration or cycling condition, and resistance limits through the cyswllt page. If the failure mode is uncertain, use the RFQ form to ask for sample evidence before changing tooling or plating.
FAQ
What is fretting corrosion on stamped contacts?
It is wear and oxide buildup caused by small repeated motion at a cyswllt interface, often leading to higher or unstable electrical resistance.
Does thicker plating prevent fretting?
Not always. Plating thickness helps only when the finish, cyswllt force, mating surface, motion, and cleanliness are also suitable for the application.
How should fretting risk be tested?
Cyffredin checks include resistance before and after cycling, vibration, thermal exposure, visual cyswllt inspection, and force measurement in the installed condition.
What should be sent for a fretting corrosion review?
Anfon drawings, material, plating, mating finish, cyswllt force, movement source, environment, resistance limit, sample quantity, and report needs.

